Automated high precision solution preparation apparatus

ABSTRACT

The present invention relates to an automated solution preparation apparatus having containers for holding solid reagents, a dispensing mechanism for dispensing the reagents to a balance, a supply for providing liquid to rinse the reagents from the balance into a chamber where additional liquids can be added, and a manifold connected to the chamber for dispensing the solution into receptacles. The chamber can have probes for monitoring properties of the solution, and heating and cooling jackets for adjusting the solution temperature. The present invention also relates to a method for using the automated solution preparation apparatus to prepare solutions of different concentrations and properties by dispensing reagents from containers into a weighing zone, where each reagent is separately weighed and rinsed from the weighing zone into a chamber, diluting the reagents with additional liquid solvent to prepare the solution and discharging the solution from the chamber into receptacles.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. application Ser. No.13/426,261 filed Mar. 21, 2012, which claims the benefit of U.S.Provisional Application No. 61/466,340, filed Mar. 22, 2011. Thecontents of the above-mentioned prior applications are hereby expresslyincorporated herein by reference in their entirety for all purposes.

FIELD OF THE INVENTION

The invention relates to a computer automated apparatus used toautomatically prepare chemical and biological solutions such as buffers,culture media, pharmaceutical preparations and other liquid mixturesthat would be used for example in the pharmaceutical, chemical,biochemical or food industries, and a method of preparing such liquidmixtures using the disclosed apparatus.

BACKGROUND OF THE INVENTION

Many solutions are routinely used in laboratories and processingfacilities for preparing sample batches and other liquid mixtures, astest solutions, or as stock solvents and mobile phases. Preparing suchsolutions requires much time to calculate the amount of reagents anddilutants, weigh the solid reagents, measure out the volumes of liquidsfor dilution, and combine these solution components in the correctamounts. These prepared solutions also require test measurement toconfirm that they are the proper concentration or have the correctcharacteristics such as pH, conductivity or turbidity for their intendeduse. During the solution preparation and testing, the technician orscientist can be exposed to harmful chemicals and vapors that can damagetheir health. If a mistake is made during any of these steps, thepreparer must start from the beginning, wasting the time and materialsused for the solution preparation. Furthermore, the time spent makingthese solutions detracts from more valuable research and other dutiespersonnel could be engaged in.

Different attempts have been made to automate this solution preparationprocess, such as U.S. Pat. No. 4,830,508 to Higuchi et al., but theyhave not fully automated a solution preparation process involvingmultiple solid reagents and liquid components in an accurate enoughmanner from multiple reagents to prepare solutions for a full range oflaboratory and facilities uses. One such automated apparatus disclosedby Legrand and Bolla in “A fully automatic apparatus for chemicalreactions on a laboratory scale,” J. Automatic Chem., March 1985, is acustom laboratory device to be used when it is impractical to scale up abench-top reaction. Such a custom device is used for running a chemicalreaction, and is not intended to or capable of performing all thesolution preparation tasks in the automated manner and at the scale ofthe present invention. Other devices have been devised to measure outliquids or premixed solutions to obtain specific concentrations ordilutions, but such devices still require the initial manual preparationof solutions that include solid reagents, which are then furtherdiluted, such as that disclosed in U.S. Pat. No. 5,833,364 to Rushing etal., U.S. Pat. No. 5,402,834 to Levin et al., U.S. Pat. No. 4,415,446 toOsbom, and the Chem+Mix™ automated solution Preparation System marketedby CHATA. Device that measure out solids to form a solution are known inrelation to the cleaning industries where concentrated wash solutionsare prepared by adding detergents to a solvent, such as that disclosedin U.S. Pat. No. 4,964,185 to Lehn and U.S. Pat. No. 5,607,651 to Thomaset al., and in the paint and pigment industries where solid materialsare metered out and blended with liquid components, such as in U.S. Pat.No. 6,827,478 to Becker et al. These devices, however, lack the featuresof the present invention that facilitate the accurate preparation oflaboratory solutions. Similarly, other devices may measure out aspecific amount of reagent or solution, but do not combine multiplecomponents to form a solution or monitor and adjust the characteristicsof the solution being prepared. Other device prepare multiple reactionsolutions for screening reactions and products in chemical andbiochemical laboratories, such as in U.S. Pat. No. 7,361,309 to Vann,U.S. Pat. No. 4,476,999 to Bilbery, and U.S. Patent ApplicationPublication 2005/0047964 to Nishida et al. These devices dispense liquidreagents, but do not weigh out solid reagents to prepare a solution. TheAccelerator™ SLT100/106/112 marketed by Chemspeed Technologies® preparessmall amounts of reaction solutions from solids and liquids, andconducts reactions, but lacks the features necessary to produce largeramounts of laboratory solutions.

SUMMARY OF THE INVENTION

Principles of the present invention relate to an automated apparatusthat can automatically prepare solutions of a predeterminedconcentration from solid reagents and liquid components havingpredetermined chemical and physical characteristics with an accuracythat makes the prepared solution suitable for the majority of laboratoryand facilities uses. According to such principles of the presentinvention it may be possible to reduce the amount of time routinesolution preparation takes, and the amount of time technicians andscientists may be exposed to the solution, reagents and solvents. Someof the non-limiting embodiments of the invention may for example providean apparatus that can deliver highly reproducible and reliable solutionsby eliminating the variations in concentrations and properties resultingfrom the variability and human error present in the manual preparationof such solutions, and to thereby meet required quality controlstandards of laboratories and facilities. Another objective of theinvention is to reduce waste of laboratory reagents due to mistakes madein the preparation of such solutions, and reduce the money and spacerequired for laboratory glassware and other materials. Some embodimentsof the invention can also maintain suitable and necessary records to becompliant with current good laboratory practices and good manufacturingpractices.

In the case of non-limiting embodiments of the present invention, theterm “predetermined” is to be interpreted as having been specificallyselected by the user or set as a parameter in a computer file used toprepare the solution, and not changed or otherwise adjusted by the useronce the automated preparation process has started.

In some embodiments, the user can choose to adjust the final solutionparameters while the solution is still being prepared.

One or more of the embodiments of the present invention relate to asolution preparation apparatus comprising a plurality of containers forholding reagents, wherein the reagents held in the containers are solidreagents; a dispensing mechanism in flow communication and operativelyassociated with each container for selectively and sequentiallydispensing an amount of one or more reagents from the one or morecontainers, wherein the dispensing mechanism comprises a plurality ofconduits connected to the egress end of the respective containers, and aplurality of valves connected to and in flow communication with theconduits where a single valve is connected to each of the plurality ofconduits; a balance for sequentially receiving dispensed reagent(s) andweighing each received reagent, wherein the balance has one or morebalance plate(s), which are suspended below the egress ends of theconduits of the dispensing mechanism and suitably dimensioned forreceiving and weighing a plurality of sequentially dispensed reagents atthe same time without loss of any reagent from the balance plate; asupply for providing liquid for removing the reagents from the balanceand for forming a concentrated solution, wherein the liquid ispreferably deionized water, and further wherein the liquid is providedto the weighing zone through suitably sized piping and at a pressurethat produces a suitable spray to wash the reagents from the balanceplates; a chamber for receiving the concentrated solution and additionalliquids for preparing a liquid mixture or solution of a predeterminedvolume, wherein the chamber has a chamber wall that can be insulated formaintaining the chamber at a consistent temperature and also has heatingand cooling jackets within the chamber wall for adjusting thetemperature of the chamber and solution; probes associated with thechamber for monitoring chemical and physical properties of the solution;and a solution distributor in fluid communication with the chamber fordispensing the solution into receptacles. The apparatus can furthercomprise one or more liquid reagent dispensers that can provide one ormore liquid reagents to the chamber, wherein the liquid reagents can beacids, bases, buffers or detergents or solutions of acids, bases,buffers or detergents for adjusting the properties of the solution beingprepared.

Embodiments of the apparatus can further comprise a volume detector inoperative association with the chamber for determining the volume ofsolution within the chamber, wherein the volume detector comprises aninfrared light source, floating disc and a detector in operativeassociation with the light source and floating disc, that measures theliquid level in the chamber by detecting when the floating disc blocksthe infrared beam at a particular level. The level of the floating disccorrelates to a particular volume of solution in the chamber.

In another embodiment, the apparatus can further comprise a sterilizertank for eliminating biological organisms and contaminants, wherein thesterilization tank is located in between and in liquid communicationwith the chamber and the manifold, and filters for removing particulatesfrom the solution before discharging the solution into one or morereceptacles. The apparatus can further comprise filters for removingparticulates from the solution before dispensing the solution intoreceptacles, wherein the filters are located in and in fluidcommunication with the solution distributor. The filters can be locatedat the ingress or egress opening(s) of the sterilization tank or at theone or more ingresses or egresses of the manifold, such that the filtersare located within the flow path of the solution to remove particulateswhen the solution passes therethrough. The solution can be sterilizedand filtered in either order, but in either case before being dischargedto the receptacles. The receptacles are preferably plastic or glassbottles, but may also be cartons, cans, bags, totes, or other containersknown in the art for storing, dispensing and transporting solutions.

Embodiments of the apparatus can further comprise a processor forcontrolling the dispensing, weighing, mixing, adjusting and dischargingprocesses. The processor can also receive signals from probes, sensorsand detectors conveying information about solution properties, processsuch signals, and send control signals to valves, pumps, heating orcooling devices, stirrers or other actuators to adjust the concentrationor properties of the solution. The processor can monitor the weights orvolumes of the solid and liquid reagents, bulk solution and finaldispensed solutions through weight or volume sensors, and record suchinformation to properly document the preparation of the solution incompliance with current good laboratory and manufacturing practices(cGLP, cGMP). The processor can also store programs for operating theapparatus, files with instructions for automated preparation ofpredetermined solutions, and data obtained from the probes, sensors anddetectors regarding the preparation of a solution, in the associatedmemory, where the memory can be both static and dynamic. The memory canbe RAM, a hard drive, a CD or floppy drive, a memory card or any othertype of transient and non-transient memory known in the art. Theprocessor, memory, interface cards, and peripherals can be a dedicatedcontroller or a stand-alone computer such as a personal computer (PC).

Embodiments of the apparatus can further comprises a plurality ofseparate compartments, wherein each separate compartment houses adifferent subset of the apparatus components, and wherein thecompartments can be sealed from the outside atmosphere, and theatmosphere inside the chamber may be temperature and/or humiditycontrolled. Access to each chamber can be by one or more access port(s)having door(s) or airlocks that can foam an airtight seal between thecompartments and the outside environment. Each compartment is alsoseparated and seal from the other compartments so that each may maintaina different controlled environment. Each of the compartments may alsohave a separate exhaust for removing gasses, vapors, dust or otherairborne contaminants and maintaining a safe and proper atmosphere.

In a preferred embodiment of a solution preparation apparatus, theapparatus comprises a plurality of containers for holding canisters; aplurality of conduits, wherein a single conduit is connected to and inflow communication with an egress end of one of the plurality ofcontainers; one or more canisters containing solid reagents placedwithin a respective container, and connected to the egress end of thecontainer so as to form an airtight seal between the canister and theconduit; a dispensing mechanism comprising a plurality of valvesconnected to and in flow communication with the plurality of conduits;and a dispenser block supporting the valves and conduits, such that thedispensing mechanism is operatively associated with each container thatselectively and sequentially dispenses an amount of one or morereagents; a balance comprising one or more balance plate(s) thatsequentially receives the dispensed reagent(s) from an egress end ofeach of the plurality of conduits, and weighs each received reagent; asupply that provides liquid to the balance for removing the reagentsfrom the balance and forms a concentrated solution; a chamber thatreceives the solution of solid reagents and liquid from the balance; avolume setting system that determines the volume of solution within thechamber; a pump that delivers liquid to the chamber until the volumesetting system indicates the solution has reached a predeterminedamount; and a valve that releases the solution from the solution into amanifold that dispenses the released solution into one or morereceptacles. The apparatus may further comprise a sterilization tank,which is suitable for destroying biological contaminants, between thechamber and manifold, connected to the egress end of the chamber belowthe chamber valve and having an outlet connected to the dispensingmanifold.

Embodiments of the present invention also relate to a method ofpreparing solutions which comprises providing a plurality of reagents;selectively and sequentially dispensing reagent(s) from reagentcontainers into a weighing zone, wherein the amounts of the one or morereagents dispensed into the weighing zone are each individuallycontrolled by a computer actuated valve; receiving the reagentsselectively and sequentially in the weighing zone, wherein eachdispensed reagent is separately weighed; providing a liquid solvent;spraying the liquid solvent into the weighing zone for rinsing thedispensed reagents from the weighing zone; rinsing the one or moredispensed reagents from the weighing zone into a chamber with the sprayof liquid solvent and foaming a concentrated solution; receiving theconcentrated solution from the weighing zone in the chamber; providing aliquid solvent to the chamber to dilute the concentrated solution ofsolvent and dispensed reagents; diluting the concentrated solution ofsolvent and dispensed reagents from the weighing zone with additionalliquid solvent to prepare a solution of predetermined concentration;discharging the solution of predetermined concentration from the chamberto one or more solution receptacles.

The method can further comprising providing one or more liquid reagents;injecting one or more of the liquid reagents into the concentratedsolution of solvent and dispensed reagents received in the chamber,wherein the liquid reagents adjust one or more properties of theconcentrated solution including pH, conductivity, surface tension, orsuspended particles, to produce a final solution having a predeterminedconcentration and physical and chemical properties, wherein the physicaland chemical properties of the present invention can be determined bysuitable probes transmitting signals to a processor.

The method can also further comprise detecting signals from the balance,calculating the amount of additional reagents to dispense to the balancebased on the signals received by a processor, dispensing additionalreagent to the balance until the processor determines the correct amountof reagent has been dispensed to prepare a solution of the predeterminedconcentration, and sending a control signal to an actuator stopping thedispensing of reagent to the balance.

The embodiments of the method can also further comprise detectingsignals from the probes, sensors or detectors associated with thechamber, calculating the amount of additional liquid reagents todispense to the chamber based on the signals received by a processor,dispensing additional liquid reagent to the chamber to adjust one ormore chemical or physical properties of the solution until the processordetermines the correct amount of liquid reagent has been dispensed toprepare a solution of the predetermined chemical or physical properties,and sending a control signal to an actuator stopping the addition ofliquid reagent to the chamber.

The embodiments of the method may also comprise recording the values ofthe amounts of reagents and solvents dispensed, the concentration andphysical and chemical properties as measured by probes during thepreparation and once completed, and storing the recorded information inaccordance with cGLP and cGMP requirements.

The principles of the invention also relate to a non-transitory computerreadable medium that can be implemented that stores machine readableinstructions for performing a process or method such as the examples ofprocesses, methods, and steps described herein, or variations thereof aswould be understood by a person of ordinary skill in the art.

Embodiments of the invention also relate to a non-transitorycomputer-readable medium that stores computer-readable instructions forexecution by a processing system, the computer readable instructions forpreparing solutions comprising; instructions to activate a valve forselectively and sequentially dispense reagent(s) from reagent containersinto a weighing zone; instructions to separately weigh each of theselectively and sequentially dispense reagent(s); instructions toactivate a pump for providing one or more liquid reagents for rinsingthe one or more dispensed reagents from the weighing zone into achamber; instructions to activate a pump for providing a liquid solventto the chamber to dilute the concentrated solution; and instructions toopen a valve for discharging the solution of predetermined concentrationfrom the chamber to one or more solution receptacles.

The embodiments can also comprise a processor that can read theinstructions from a computer readable medium and cause thecomputer-controlled components to perform the steps of the differentembodiments of the invention and to carry out any one of the methodsdisclosed herein. The electronic device can also comprise theelectronics necessary for communication with the computer controlledcomponents, for example the valves, probes, pumps, stirrers, and othercomponents, as would be known to those of skill in the automation arts.

BRIEF DESCRIPTION OF THE DRAWINGS

The above features and other advantages of the invention will becomebetter understood by reference to the following detailed description ofpreferred embodiments and the accompanying drawings wherein:

FIG. 1 is a front view of an automated solution preparation apparatusillustrating a preferred embodiment of the present invention.

FIG. 2 is a detailed view of a preferred embodiment of the containersand dispensing mechanism.

DETAILED DESCRIPTION OF THE INVENTION

It should be understood that the figures and following descriptions areof exemplary embodiments of the present invention and are not intendedto limit the scope of the invention in any manner. Other variations andembodiments of the present invention would be apparent to persons ofordinary skill in the art without departing from the spirit andprinciples of the invention, and all such variations and embodiments areintended to be included within the scope of the disclosure for thepresent invention and protected by the accompanying claims.

In an example of a preferred embodiment, an apparatus 1 having foursections 2, 3, 4, 5, can automatically prepare solutions ofpredetermined concentrations from solid reagents and liquid componentshaving predetermined chemical and physical characteristics with anaccuracy that makes the prepared solution suitable for the majority oflaboratory and facilities uses. As shown in FIG. 1, an embodiment of theapparatus has a plurality of containers 10 for holding reagents, adispensing mechanism 20 for selectively and sequentially dispensing oneor more reagents, a balance 30 for weighing each received reagent, oneor more spray nozzle(s) 40 connected to and in fluid communication withpumps 50 for pumping solvent to the spray nozzles for rinsing reagentsfrom the balance with bursts or sprays of the solution solvent, acollector 60 that collects the concentrated solution of reagent(s) andsolvent from the sprays and directs the concentrated solution to thechamber 70 for adjustment of the solution properties and dilution to afinal volume and concentration, wherein the chamber 70 has stirrers 75,walls 80 that can have insulation 85, a funnel shaped bottom 88 with adrain 90, a heating jacket or coil 100, and/or a cooling jacket or coil105. The heating and cooling jackets or coils 100, 105 can havereservoirs 101, 106 that help to maintain a stable temperature and flowof heating or cooling fluid. The heated or cooled fluid is circulatedthrough the respective reservoir, jacket and/or coils.

The chamber 70 can have probes, sensors or detectors 110 for measuringvarious properties of the solution as it is being prepared. A pump 120in fluid communication with the chamber 70 and a solvent supply 130 canpump solvent into the chamber 70 from the solvent supply 130 to increasethe volume of solvent in the chamber 70 to a final level detected by avolume setting system 140, wherein the volume setting system can have atransmitter 142, a floating disc 145 and a detector 147 in operativeassociation. Liquid reagents in reagent reservoirs 150 can be added tothe chamber 70 by pumps or injectors 160 in fluid communication with theliquid reagent reservoirs 150 and chamber 70.

The prepared solution having a predetermined concentration exits thechamber through the drain 90 when valve 95 is opened and optionallyflows to a sterilization tank 170 for killing undesirable biologicalcontaminants, and then to a solution distributor 180. If there is nosterilization tank 170, the final prepared solution having apredetermined concentration and physical and chemical properties canflow through the chamber drain 90 to the solution distributor 180,wherein the solution distributor can be a manifold for dispensing to thesolution receptacles 200. Such a manifold may comprise a series ofinterconnected pipes or conduits that evenly and uniformly conveys thesolution to the final receptacles. The solution may also be filteredthrough filters 190 located either at the egress(es) of thesterilization tank 170 or at the ingress(es), egress(es) or within thesolution distributor 180. In some embodiments, the manifold can beseparate pipes or conduits connected to the egress ends of the filtersin order to maintain any differences in the solutions due to the size ortype of filter used. In other embodiments, the solution can be drawninto the sterilization tank or through the filters using a vacuum 210,or forced through the filters under pressure (not shown).

Various embodiments of the apparatus are controlled by a processor 220with associated memory 225 such as a personal computer. The computerwould have sufficient transient RAM memory, non-transient storagememory, processing power, and hardware, such as interface cards to runthe associated control software, interface with and operate theautomated components of the apparatus, such as the various pumps,valves, sensors, and detectors, and record the values from the sensors,probes and detectors.

In some embodiments, the reagent containers 10 and dispensing mechanism20 can be within a first compartment 300 that isolates the containers 10and dispensing mechanism 20 of the first section 2 from the outsideatmosphere and the other sections 3, 4, 5, of the apparatus 1 withoutinterrupting the reagent flow communication between the dispenser andthe balance 30. The balance 30, spray nozzle(s) 40, and collector 60,can likewise be within a second compartment 325, which isolates section3 from the outside atmosphere and the other sections 2, 4, 5, withoutinterrupting reagent flow or liquid communication between the dispensingmechanism 20 or chamber 70. The chamber 70, drain 90, probes 110, volumesetting system 140, liquid reagent reservoirs 150, and injector(s) 160,are within a third compartment 350, that isolates the third section 4,from the outside atmosphere and the other sections 2, 3, 5, withoutinterrupting liquid communication between the collector 60 andsterilization tank 170 or solution distributor 180. The sterilizationtank 170, solution distributor 180, filters 185, and receptacles 200 arewithin a forth compartment 375, that isolates the forth section 5, fromthe outside atmosphere and the other sections 2, 3, 4, withoutinterrupting liquid communication between the chamber 70 and drain 90,and the sterilization tank 170 or solution distributor 180. Thecompartments 300, 325, 350 and 375 may have individual access ports 305,330, 355, 380 that allow separate access to sections 2, 3, 4, 5,respectively for such things as clearing clogs, making repairs orreplacement of components.

In embodiments of the present invention, multiple reagent containers 10are situated in the first compartment 300 at the top of the apparatus 1above the other components. These containers 10 are sized and shaped tohold specially designed canisters 11 that preferably contain solidreagents. The containers can preferably be cylindrical, but can also behexagonal, square, rectangular or any other shape that can be arrayed ina regular pattern while allowing access for changing their contents. Theterm solid is meant to include all solid particles having a sufficientlysmall size and either regular or irregular shapes, such as powders,crystals, pellets, grains, flakes, filings, shavings, dust, etc. Thisplurality of containers is arranged in a regular manner such that theycould be operatively associated with the dispensing mechanism. Thecanisters 11 are also sized to hold sufficient amounts of reagents forpreparing a plurality of solutions before having to be replaced, andshaped to fit within the containers 10 in a manner that provides easyinsertion and removal, such as a slip fit. The canisters can alsopreferably be cylindrical, but can also be hexagonal, square,rectangular or any other shape that can preferably be arrayed in aregular space-saving pattern. The canisters 11 in a preferred embodimenthave a spout at a bottom end that is closed with a removable cap, and anopening at a top end opposite the first end that has a removablecovering. The canister 11 can be inserted into the container 10 by firstremoving the cap from the spout at the first end and placing thecanister bottom end first into the container. The spout at the bottomend of a canister 11 is suitably configured and dimensioned to join withthe ingress end of the dispensing mechanism 20, and preferably forms aseal between the canister and the dispensing mechanism 20. In apreferred embodiment, after the cap is unscrewed from the spout, thespout is screwed into the ingress end of a conduit 25. A seal is alsopreferably formed between the canister 11 and the container 10, such asby a gasket or bevel (not shown). Each of the seals preferably preventsthe entry of contaminants, gasses and moisture into the canisters andconduits. The removable covering can then be removed from the top end ofthe canister to prevent a vacuum from forming in the canisters so thereagent flows smoothly. There can be a mesh or screen or othersemi-permeable membrane secured over the top opening to protect thereagent from contaminants, gasses or moisture after the covering isremoved. The caps and coverings are preferably screw caps but may alsobe snap lids, foil pull-seals, or any other type of removable closureknown to those skilled in the art.

In some embodiments, the dispensing mechanism 20 comprises an array ofconduits 25, an array of valves 15, and a dispenser block 22, such asflexible tubing or more rigid piping that are in flow communication withthe array of containers 10 holding the canisters 11 of the solidreagents. The ingress ends 21 of the array of conduits 25 are arrangedin the same pattern as the array of canisters and containers, such thatthe conduits match up and become associated with the canisters to allowsolid reagent to flow from any or all of the multiple containers to alocation above the weighing zone 33 of a balance 30. The conduits can beattached to the egress end of the containers with a disengagableconnector such as a threaded coupling or it may be permanently attachedusing a permanent adhesive, brazing, soldering or welding depending uponthe materials being used for the respective components. Flow of thesolid reagents is controlled through the use of valves 15 activated byand in operative association with dispensing mechanism 20, wherein eachconduit has its own independently controlled valve that prevents thesolid reagent from a particular container from being dispensed to theweighing zone 33 of the balance 30. The valves 15 may be located at theingress end of the conduit, or more preferably at the egress end or atsome position between the two ends of the conduits within the dispensingmechanism 20. In the best mode, as illustrated in FIG. 2, the valves 15are held in a regular array within the dispenser block 22, and eachvalve is connected to and in flow communication with the egress end 29of a conduit. Each valve is therefore associated with and in flowcommunication with a specific container and canisters through therespective conduit. The dispenser block can be a solid block holding orincorporating the valves, or it may also be a series of walls separatingthe array of valves from each other to prevent cross contamination ofreagents, and covers to close the openings in the block. FIG. 2 depictssuch an arrangement of valves located in a solid dispenser block and inflow communication with the conduits and containers (where some featuresand duplicated components are not drawn to maintain the clarity of thedrawing). The dispenser block and valves also act as a seal betweencompartment 300 and compartment 325 when the valves or dispenser blockopenings are closed. In the preferred embodiment, the valves anddispenser block are placed as close to the balance as possible withoutinterfering with the dispensing or weighing operations to provide themost accurate method of weighing the reagents. Placing the dispenserblock and valves as close to the balance plate as possible reduces theamount of material present in the gap between the two components thathas not yet been weighed. In an embodiment where the valve are locatedby the containers, along the conduit, or otherwise away from thedispenser block, the egress ends of the conduits are preferablyconnected and in flow communication with the openings in the dispenserblock 22, and the dispenser block has doors, slides or other covers thatcan close the openings in the dispenser block to preferably prevent theentry of reagents, solvents, gasses, vapors, moisture or othercontaminants into the conduits and compartment 300 from the weighingarea 33 of the balance 30, or from compartment 325.

When a valve 15 is opened, solid reagents may flow through the conduits25 by gravity feed, or the particle flow may be augmented or furthercontrolled by known feed assist mechanisms and methods such as augers,vibratory mechanisms and feeders, entrainment by venturi systems,compressed air-assist, blowers, other types of positive pressure orvacuum, etc. In a preferred embodiment, one or more feed assistmechanisms may also be present to facilitate the flow of any reagentsfrom the containers and canisters through the conduits and valves to theweighing zone 33 of the balance. The rate at which a solid reagent isreleased from a container or a conduit is preferably controlled byrestricting the time and/or extent to which the valve is opened. Theterm “extent” is to be interpreted as the available cross-sectional areaof the valve opening across which there is a flux of materialindependent of the design of the valve mechanism, and restricting theextent should be interpreted to mean changing the cross-sectional areain a manner that reduces the flux of material through the valve due to asmaller opening and/or a reduction in flow velocity of material. Forexample, the valve opening may be contracted or restricted to reduce therate of flow when the balance registers that a predetermined amount hasbeen dispensed to more slowly approach the final weight, and therebyachieve more accurate control of the total amount dispensed. In anotherembodiment, the valve opening could also remain open until the balanceregisters for example 99% of the final weight, and then be fully closedwith the expectation that the amount of reagent dispensed in the briefinterval before the valve completely closes will still be sufficientlyaccurate. The actual percentage of weight dispensed before closing thevalve would be determined based on the flow properties of the solid,such that a known or calculatable amount of solid powder would exit thevalve before it was fully closed. This amount or weight of material canbe determined and calibrated by the processor quickly opening andclosing the valve for a specific reagent a predetermined extent multipletimes and measuring the actual amount dispensed to the balance with eachsuch cycle of the valve. The actual dispensed amounts can then becompared and averaged to determine the weight at which a specific valvefor that particular reagent should be closed to accurately achieve theneeded final weight. This method avoids the user having to prepare newcalibration standards for each solution or perform other measurements tocalibrate the apparatus.

The dispensing mechanism 20 can selectively dispense each reagent, asspecifically required to prepare a solution, in a sequential manner tothe weighing zone 33 of the balance. This results in a dispensing cyclewhere the dispenser opens the valve to the first required reagentthereby allowing the solid to flow to the weighing zone, and when thecorrect weight of this first reagent is reached, the valve stops theflow of that reagent, and opens the valve to the next required reagent.The dispenser 20 repeats this cycle until all the required solidreagents for preparing the specified solution have been sequentiallydispensed to the weighing zone in the correct amounts. Once a reagent isdispensed and properly weighed, it does not matter if subsequentlydispensed reagents intermix with the prior ones because the amount ofeach dispensed reagent is determined by the difference in weight at thebeginning and end of a dispensing cycle. The sequence of dispensing eachreagent, however, may be chosen to facilitate the flow of each reagentby dispensing sticky, foaming or very fine materials in a preferredorder. This cycle can be repeated as many times as is required todispense all the reagents needed to prepare a specific solution.

In embodiments of the invention, the balance(s) 30 receive(s) thedispensed reagents in a weighing zone 33. The weighing zone can includeone or more balance plates 36, where a single balance plate would have asize sufficient to hold the total amount of reagents that would be usedto prepare any of the required solutions. The balance plate 36 isappropriately sized and shaped to be capable of retaining the totalamount of the one or more reagents received in the weighing zone 33, andobtain an accurate final weight by avoiding any reagent falling off thebalance plate. In some embodiments, a number of balance plates ofdiffering sizes from ½ liter to 100 liters can be provided for theuser's selection based upon the amounts of materials to be accuratelyweighed, and exchanged as needed before solution preparation. Two ormore balance plates may also be placed within the weighing zone forimproved accuracy and precision in weighing greatly different amounts ofreagents with a diverter or orientatable nozzle (not shown) to directeach reagent to the appropriately sized balance plate. Each balanceplate would have a size appropriate for holding and accurately weighinga portion of the total amount of reagents to be used to prepare arequired solution. Having two or more balance plates within the weighingzone also avoids the need to exchange balance plates during a solutionpreparation.

Preferably each of the one or more balance(s) is a high precisionsuspended balance, where the balance plate is connected to a precisionweighing mechanism or load cell outside the weighing zone and shieldedfrom the solvent spray and solid reagent dust. The balance plate(s) canbe suspended below the egress ends of the conduits comprising thedispensing mechanism. Some embodiments contemplated for the presentinvention would utilize two balances with one having a large balanceplate dedicated to weighing large weights, and the second balance havinga small balance plate dedicated to weighing smaller weights, where theprecision and accuracy of the smaller balance could be greater than theprecision and accuracy of the larger balance.

Embodiments of a balance plate preferably have vertical or inwardlyslanted walls that would act to retain dispensed materials on thebalance plate's base. The base plate can be a single plate, orpreferably it may be divided into two or more sections that act asdoors, which open slowly to prevent lighter or fluffier materials fromdispersing or being suspended in the air when being transferred to thechamber 70. The sections or doors of the base plate are preferablyattached to the walls of the balance plate. The base plate or pluralityof opening sections can have on or more pneumatic or hydraulic pistonsor actuators to open or close the plate section(s).

Each of the one or more balance plates' walls and base(s) can be sprayedwith a liquid solvent from spray nozzles 40 to aid in transferring theweighed solid reagents into the collector funnel 60 and chamber 70.

The balance can measure the weight of each reagent as it is sequentiallydispensed to the weighing zone 33. The balance 30 determines the amountof the solid reagent received on the balance plate 36 by registering theinitial weight of the plate and any previously received reagents beforethe next reagent is dispensed, and the accumulated weight after thereagent is dispensed. The balance 30 detects the difference between theinitial weight and accumulated weight to determine when the final weightis obtained. The processor can receive the weights from the balancesensors, and calculate when the final weight is obtained. The weighingproceeds one reagent at a time in a sequential manner until allnecessary reagents have been dispensed. The weight of each sequentiallydispensed reagent is recorded for the preparation of the solution inaccordance with cGLP and cGMP requirements.

The each of the one or more balances 30 has sufficient precision andaccuracy to weigh out an amount of reagents within a toleranceacceptable for the lab or production facility within a prescribed rangefor the balance's size. Preferably, each balance is capable ofaccurately weighing to within 0.001 gram, but the demands of theparticular use may require a more accurate balance or allow the use ofone with less accuracy, also depending upon the total amount of materialto be weighed by the particular balance. A person of ordinary skill inthe art will be aware of the necessary accuracy and precision for theirown particular uses.

Reagents dispensed to the balance(s) 30 can be washed after weighingfrom the weighing zone 33 and balance plate(s) 36 with bursts or spraysfrom spray nozzles 40 of the liquid being used as the solvent componentof the prepared solution. The liquid is provided to the weighing zonethrough suitably sized piping and at a pressure that produces a suitablespray to wash the reagents from the balance plates. These bursts orsprays of solvent reach all surfaces of the weighing zone 33 and washall of the dispensed solid reagents from the balance plate 36 into acollector 60. The solvent is preferably forced from the solvent source130 through suitable piping to the spray nozzles 40 by pumps 50 that arein fluid communication with the spray nozzles 40 and solvent source 130,and can generate bursts or sprays of suitable pressure to rinse all thereagents from the weighing zone without requiring a quantity of solventgreater than would be needed to prepare a solution of a particular finalconcentration. The collector 60 can be a funnel or other suitably shapedfeature that directs the concentrated solution into the chamber 70 whileavoiding the trapping or adhering of any residue reagent powders orsolution. This first solvent spray prevents any of the dispensedreagents from remaining in the weighing zone 33, and ensures that thetotal amount of weighed reagents is included in the chamber. Thecollector is preferably washed by a second solvent spray that preventsany of the concentrated solution washed from the weighing zone fromremaining in the collector. The second solvent spray rinses the bottomof the balance plate and the reagent and solution from the first sprayfrom the collector 60 to the chamber 70. The amount of solvent used towash the weighing zone 33, balance plate 36 and collector 60 is lessthan the total volume that will be used to prepare the final solution ofthe predetermined concentration. The combination of solid reagents andsolvent at this stage therefore forms a concentrated solution that willbe diluted to a final volume and concentration in the chamber 70. Thecollector 60 can be a funnel that directs the concentrated solution ofsolid reagents and solvent into the chamber 70. The first and secondsolvent sprays ensure all of the reagents weighed out in the balance 30are quantitatively transferred to the chamber 70 for final dilution.This quantitative transfer of material helps to achieve theconcentration of the final solution within the expected accuracy andprecision.

The solvent 130 would preferably be water, and more preferably highpurity deionized water, but may also be a saline solution, alcohol,acetone, hexane, or some other aqueous-based or organic liquid. Theparticular choice will depend on the type of final solution the user maytypically be preparing. Examples of possible uses include liquidchromatography mobile phases, buffer solutions, biological orbiochemical media, electrophoresis gels, colloids, or reactionsolutions.

In some embodiments of the present invention, the liquid reagents arestored in the liquid reagent reservoirs 150, which can be acids, bases,surfactants, detergents or other polymers, as well as organic liquidslike dyes and those listed above. The acids could be mineral acids suchas phosphoric, sulfuric, nitric or hydrochloric acids, or organic acidssuch as acetic, oxalic, malic, tartaric or citric depending upon thetype of solution to be prepared and the type of buffer system beingused. Such solutions can be prepared by the apparatus and then used as asolvent or liquid reagent. The user of the apparatus 1 would select thematerials that would be appropriate for the particular solutions thatthe user would be preparing without limitation to the materialsmentioned. One or more pump(s) 120 and/or injector(s) 160 feed thesolvents and liquid reagents into the chamber. The pump(s) 120 feed thesolvent(s) into the chamber until the necessary volume is reached, atwhich time the pump(s) are shut off. Liquid reagents are transferred byinjector(s) or pump(s) 160 from the reagent reservoirs 150 into thechamber 70 until a particular property of the solution, such as pH, isreached, and then the injector or pump stops.

The concentrated solution is received in a chamber 70. The chamber canhave walls 80 made of material suitable to hold the solutions beingprepared without causing contamination or being damaged by thesolutions. The chamber walls 80 can be insulated 85 and furthersurrounded with heating and/or cooling jackets or coils 100, 105 tocontrol the temperature of any solution being prepared. The heating andcooling jackets or coils can have reservoirs 101, 106 to help maintain astable temperature and constant flow of heating or cooling fluid. Theheated or cooled fluid is circulated through the respective reservoirand jacket to adjust and/or maintain the chamber and solution at asuitable and stable temperature. Preferably the chamber, heating andcooling jackets are stationary and does not need to be raised or loweredto receive solution, or be heated/cooled. The solution is received fromthe collector 60 directly into the chamber 70. An egress from thechamber 70 in the form of a drain 90 having a valve or a plug 95 thatprevents the flow of the solution from the chamber is preferablypositioned at the bottom of the chamber in a manner that would allow allof the solution to leave without pooling or leaving more than a minimumof residue. The chamber preferably has a funnel shape that directs allof the solution out through the drain 90. The drain is in liquidcommunication with a solution distributor 180 that can be a liquidmanifold and/or a tank with one or more egresses that directs the finalprepared solution to empty receptacles 200 for easier distribution,storage, and later use. The distributor can be configured anddimensioned to allow filling of receptacles from ½ liter to 10 liters,or more preferably from 1 to 4 liters in size, although larger orsmaller receptacles could be filled without deviating from the scope orintent of the present invention. The receptacles 200 may be for example,plastic or glass bottles, cartons, cans, bags, or totes depending on theuse and storage requirements of the user.

In various embodiments, the chamber can have devices such as probes,stirrers, detectors or analyzers 110 for monitoring the chemical andphysical properties of the solution being prepared. Such devices couldpreferably be electrodes for conductivity measurements, temperatureprobes, pH probes, solubility probes, turbidity detectors ornephelometers, specific gravity probes, optical rotation detectors, andUV, IR and NIR spectrometers. The probes, sensors and detectors monitorphysical properties of the solution such as temperature, amount ofsuspended particles, viscosity and density and send signals to aprocessor for adjusting the properties to a predetermined value byheating, cooling, or adding additional liquid reagents. Other probes,sensors and detectors can also monitor chemical properties such as pH,solubility, salinity, conductivity and chemical composition, such as byinfrared or near infrared in situ monitors, and send signals to aprocessor for adjusting such values to a predetermined level by addingadditional liquid reagents. A camera associated with the chamber 70 canalso be used to observe the solution during preparation to detectundissolved solids or other visual abnormalities in the solution.

In embodiments of the invention, a volume setting system 140 can be inoperative association with the chamber 70, and determines the volume ofsolvent added to the solution by detecting the level of solution in thechamber. The volume setting system 140 preferably uses an infra-redtransmitter that produces a linear light beam, a floating disc and areceiver that detects the location of the beam. The linear light beamtravels across the chamber 70 at a predetermined height corresponding tothe needed final volume of solution to the receiver. The receiverpreferably can be an array of infra-red detectors that positionedvertically on the side of the chamber 70 opposite the transmitter. Thereceiver detects the light beam from the transmitter until the floatingdisc interrupts the light beam, when the needed volume of solution isreached. The solvent pump(s) 120 feed solvent into the chamber until thefloating disc interrupts the infrared beam preventing the beam fromreaching the detector. The solvent feed is stopped when the volumesetting system 140 indicates the correct volume is reached. Once thelight beam is interrupted, the pumps and any active stirrers are stoppedto allow the surface level of the solution to stabilize. If the solutionlevel decreases after the surface has stabilized, the floating discceases to interrupt the light beam and additional solvent will be pumpedinto the chamber 70 until the final volume is reached. Once an accuratefinal volume is reached, the stirrers and probe will be activated toensure a homogenous solution with the required properties has beenprepared. If the solution is at the predetermined volume, but thesensors detect the solution properties are outside of the predeterminedrange(s), the processor can send a warning and request for correctiveaction to the user. Although the infrared arrangement is the preferredembodiment, other detection methods such as ultrasonic level sensors,floats, capacitance detectors, pressure sensors or other means known tothose in the art may also be used to determine the solvent level in thechamber.

In other embodiments, the solution manifold 180 may optionally beconnected to and in fluid communication with a sterilization tank 170,which is located between and in liquid communication with the chamberdrain 90 and the solution manifold 180 for sterilization of the finalprepared solution and filtration before distribution to the finalreceptacles. The tank can also have one or more egresses that are influid communication with the receptacles through suitable tubing orpiping. Filters 190 can be fitted in the one or more sterilization tankegresses to remove unwanted particulates of a particular size or largerbefore the solution enters the receptacles 200. Filters 190 can also befitted within each fluid communication path to provide greaterfiltration surfaces and avoid clogging of such filters, or to allowdifferentiation in filtration size to prepare solutions or suspensions,such as colloids, of varying grades or properties. The filters maypreferably have between 0.22 um and 0.45 um pores for example, or anyother pore size as known to those of ordinary skill in the art that meetthe solution preparation requirements.

The sterilizer 170 can be a heated tank that can raise the temperatureof the final solution to a temperature needed to kill biologicalorganisms or destroy biological contaminants, or it could have devicessuch a UV lighting, ozone generators, or other sterilization devicesknown to those of ordinary skill in the art for accomplishing suchsterilization. The solution can be drawn into the sterilizer tank 170and through the manifold 180 and filters 190 by a vacuum 210. The vacuumis preferably in gaseous communication with the manifold, so as tosuction the solution through the tank and any intervening conduitsforming the manifold. The vacuum in a preferred embodiment is preferablyconnected to the apparatus in such a manner so as to suction thesolution through any filters, however the solution may also pass throughthe filters under gravity. In one embodiment, the filter can be locatedat the egress end of the chamber drain 90, and the vacuum can be ingaseous communication with the sterilization tank. In anotherembodiment, the filters 190 can be located at each of a plurality ofconnecting openings between the sterilization tank 170 and the manifold180, and the vacuum is in gaseous communication with the manifold at alocation downstream of the filters 190. Suitable baffling and screensknown in the art should be used to prevent drawing the solution into thevacuum or entrainment of the solution in the vacuum flow.

In some embodiments, the apparatus is controlled by a processor 220 thathas associated memory 225 that can store programs and data. Theprocessor can read instructions from a computer readable medium andcause the computer-controlled components to perform the steps of thedifferent embodiments of the invention and to carry out any one of themethods disclosed herein. The processor is connected to peripheral inputand output device such as keyboards, mice, displays and printers, aswell as other device known to those in the art of computers andprocessors. The computer(s) can also comprise hardware, software andfirmware necessary to store, process, and communicate with a variety ofother devices, as would be known in the art. The operations of theapparatus including the dispensing, weighing, washing, diluting, mixing,and discharging are all controlled by the processor. The processor canbe connected to components of the apparatus such as the balance as wellas probes, sensors and detectors to receive information for processing,and transmit instruction signals to components or actuators such as thereagent dispenser valves, augers, vibratory mechanisms, pumps, solventsprays, liquid reagent dispensers, heaters, coolers and other devices.The components, detectors and sensors can provide feedback to thecontroller, so that it can control other components and actuators basedupon the signals and record the solution properties. This feedbackallows the processor to monitor and control the preparation of thesolution and correct for any discrepancies based upon such signals. Theprocessor receives signals from the balance 30, and probes, sensors anddetectors 110 conveying information about the solution properties,processes such signals, and sends control signals to valves, pumps,heating or cooling devices, stirrers or other actuators to adjust theconcentration or properties of the solution or advance the preparationof the solution to a subsequent step. The controller 220 can adjust theamounts of materials added to the solution to produce a final productwith the requested and necessary properties. The processor can be acomputer work station as known to those of ordinary skill in the art, oran application specific controller having all the basic components of acomputer but also with specialized components for connecting to andinteracting with all the apparatus components, sensors and actuators.

The apparatus 1 can further comprise a processor 220 for controlling thedispensing, weighing, and mixing processes. The processor 220 can alsostore an operating system and programs for operating the apparatus 1,files with instructions for automated preparation of predeterminedsolutions, including solution preparation instruction previously enteredby a user, and data obtained from the probes, sensors and detectors 110regarding the preparation of a solution, in the associated memory 225,where the memory 225 can be both static and dynamic.

The memory in association with the processor can store programminginstructions and data files that contain selections of reagents andsolution volumes for preparing particular final solutions. Theseinstructions can be activated, and/or data files read to preparepredefined solutions. Once activated the programming will control theapparatus automatically to prepare a chosen solution. For example, theprocessor 220 and memory 225 would control the sequence of the reagentsdispensed to the weighing zone 33, open and close the individual valves15 to control the weights of each reagent dispensed based upon thesignal from the balance 30, spray the solvent into the weighing zone 33to wash the reagents into the chamber 70 once all reagents were weighed,increase the volume of solvent in the chamber 70 by tuning on the pump120 for the solvent, turn on stirrers 75 to mix the solution as it isbeing prepared, and stop the pump 120 once the correct volume andconcentration are reached. The memory 225 can also store signals fromthe balance 30 and sensors 110 to monitor the changes in the solutionfor quality control and documentation purposes to meet good laboratoryand manufacturing requirements. Such documentation can then be printedout for quality control and compliance, laboratory or manufacturingrecords.

In a preferred embodiment, a user can recall a file storing instructionsand parameters for preparing a solution and loading it to the computer,where the computer 220 activates the dispensing mechanism 20 to dispensepredetermined amounts of one or more reagents to the balance 30 based oninstruction stored in a file in the memory 225. The balance 30 sendssignals to the computer 220, which continuously monitors the increase inweight for each sequentially dispensed reagent. The computer 220 sends asignal to the dispensing mechanism 20 to close the valve 15 when themeasured weight of the reagent on the balance plate 36 reaches 99% ofthe predetermined amount indicated in the instructions. The nextselected reagent is then sequentially dispensed to the balance 30 andweighed in the same manner. This is repeated until all the requiredreagents have been dispensed and weighed to the balance plate 36. Thecomputer activates the pump 50 to spray solvent into the weighing zone33 to rinse the dispensed reagent(s) from the balance plate 36 into thechamber 70. The computer 220 then monitors the solvent level andsolution properties in the chamber. The computer will turn on thestirrers 75 to ensure the solution has a uniform concentration andconsistency, or the heating 100 and cooling 105 jackets. When the volumesetting system 140 send a signal to the computer 220 that thepredetermined volume of solution has been reached, the computer 220turns off the solvent pump 120, opens the drain 95, and turns on thevacuum 210 to draw the solution out of the chamber 70, through themanifold 180 and discharges it into the awaiting receptacles 200.

Once a solution is prepared and the preparation cycle is finished, thecomputer can turn on the pumps 50, 120 to wash any remaining reagents orsolution from the apparatus. The solvent flushes all the apparatuscomponents and is discarded though a waste line that can be attached toan egress of the manifold or suctioned out using the vacuum. Largevolumes of solvent and extended durations of spraying can be used toensure all reagent and solution residue is flushed from the apparatus.Hot air produced by devices known in the art can then be forced throughthe apparatus to dry any remaining solvent and vent the vapors. In thepreferred embodiment, hot air guns flush the weighing zone compartment325 with hot air to evaporate any remaining solvent from the balance(s)30 and weighing zone walls.

The apparatus preferable can produce between ½ and 100 liters, and morepreferably 1 and 10 liters of solution at one time.

The components of the apparatus can be made from stainless steel,aluminum, non-ferrous alloys, Teflon®, high density poly ethylene(HDPE), or any other material understood by those of ordinary skill inthe art for use in particular applications that may depend on thesolution acidity or alkalinity, salinity, temperature, or other chemicalor physical properties, as well as the ability to prevent contaminationand be properly cleaned between solution preparations.

In some embodiments, the apparatus 1 preferably comprises four sections2, 3, 4, 5, in flow communication with each other that can be housedwithin four separate compartments 300, 325, 350, 375, wherein thecompartments are airtight. The compartments may each also have accessports to allow access to the apparatus components that can maintain anairtight seal when any access port or opening 310 is properly closedand/or sealed preferably with an airtight door 320. Access to eachseparate compartment would be by opening the air-tight door(s) orairlock(s) 320. By making the compartments airtight when sealed, thetemperature, humidity, pressure, and atmospheric gasses can becontrolled for prevention of contamination and maintenance of suitablepreparation conditions. The temperature, humidity, pressure, andatmospheric gasses can be adjusted with suitable devices known in theart for such purposes, such as compressed gas cylinders, heaters, airconditioners, dehumidifiers, etc. This may be particularly important inthe second section 3, where the reagents are weighed and initially mixedwith the solvent. The compartments can also be used to contain andexhaust undesirable or dangerous fumes by having the compartments inflow association with venting conduits that remove gasses or fumes orduct from the separate compartments by vacuum or positive pressure, andevacuate them to a fume hood, remediation system or the outside.

Embodiments of the present invention also relate to a method ofpreparing solutions using an automated high precision solutionpreparation apparatus comprises providing a plurality of reagents,wherein the reagents are solids that may be in a canister, loading thesolid reagents or solid reagent canisters into the solid reagentcontainers, dispensing solid reagents from the containers, wherein thesolid reagents are dispensed by automatically activating a dispensingmechanism such as valves to selectively and sequentially dispense thesolid reagent, automatically dispensing the solid reagent selectivelyand sequentially to a balance, weighing each selectively andsequentially dispensed solid reagent by measuring the difference betweenthe detected weight before the solid reagent is dispensed and the weightdetected by the balance after the selected solid reagent is dispensed.Washing or rinsing the solid reagent from the balance into a collector,and receiving the solution directed by the collector in a chamber.Prefilling the chamber with a portion less than the total volume ofsolvent needed. Adding the one or more solid reagents to the prefilledchamber. Diluting the received solution to a predetermined concentrationby increasing the volume of solvent making up the solution, and addingamounts of additional liquid reagents to affect other solutionproperties. Adjusting the chemical and/or physical properties, such asthe pH, of the solution by adding sufficient amounts of liquid reagentsto obtain the required solution property. Adding sufficient solvent tobring the volume of solution to the final predetermined amount.Dispensing the solution to a plurality of receptacles.

An embodiment of the method can further comprise stirring the solutionin the chamber to thoroughly mix the reagents and solvents, detectingphysical and/or chemical properties of the solution with probes as it isbeing prepared, discharging the solution from the chamber through adrain by vacuum; filtering the solution to remove suspended particlesbefore discharging it to a plurality of receptacles, where the solutionis pulled through the filter(s) by vacuum, sterilizing the solutionbefore discharging the final prepared solution to a plurality ofreceptacles, wherein sterilizing can be accomplished by suitably heatingthe solution, exposing the solution to UV radiation or ozone to kill anybiological organisms or destroy biological contaminants.

In another embodiment, the method can further comprise adjusting thetemperature of the chamber and solution by circulating a temperaturecontrol medium such as heated or cooled fluids through the heatingand/or cooling jackets. The method can also further comprise detectingsignals from the balance, calculating the amount of additional reagentsto dispense to the balance based on the signals received by a processor,dispensing additional reagent to the balance until the processordetermines the correct amount of reagent has been dispensed to prepare asolution of the predetermined concentration, and sending a controlsignal to an actuator stopping the dispensing of reagent to the balance.

In another embodiment, the method can also further comprise detectingsignals from the probes, sensors or detectors associated with thechamber, calculating the amount of additional liquid reagents todispense to the chamber based on the signals received by a processor,dispensing additional liquid reagent to the chamber to adjust one ormore chemical or physical properties of the solution until the processordetermines the correct amount of liquid reagent has been dispensed toprepare a solution of the predetermined chemical or physical properties,and sending a control signal to an actuator stopping the addition ofliquid reagent to the chamber.

The method can also comprise loading software into a computer foroperating the apparatus and controlling the activation of the individualcomponents of the apparatus, wherein the computer has a processor thatcan run the software and control the components of the apparatus bysending and receiving signals to the sensors and actuators. The computercan initiate preparation of a predefined solution by loading a data fileinto the computer memory or receiving input from a used through aninput, such as a keyboard, and activating the valves and feed assistmechanisms to sequentially and selectively dispense solid reagents fromeach of the one or more solid reagent containers onto a balance plate inthe weighing zone, and receiving a measurement signal from the balanceindicating an accurate real-time weight of reagent dispensed to thebalance plate. The actual final weighed amount of each dispensed reagentcan be recorded and stored in memory by the computer. The computer canthen close the valve feeding the selected reagent at the correctpredetermined weight communicated from the load cell or sensor of thebalance. Once the correct weight of each reagent has been dispensed tothe balance, the computer can activate the pumps for the solvents influid communication with the spray nozzle(s) within the weighing zone.The computer may determine the maximum amount of solvent to be used towash the reagents from the balance plates without over-diluting thesolution.

Once the concentrated solution is washed into the chamber, the computercan activate the solvent pump and increase the amount of the solution toa final volume and concentration. The computer may also receive signalsfrom the sensors in the chamber indicating the various chemical andphysical properties of the solution, and activate pumps for dispensingother liquid reagents or reactants to adjust these chemical and physicalproperties based upon the feed-back from the sensors. The computer canalso activate stirrers within the chamber to make sure the solidreagents become dissolved and the properties being measured are uniformthroughout the prepared solution. Each or the sensor reading may berecorder by the computer and software and suitable reports generated toallow the apparatus to comply with cGLP and cGMP requirements. Once asolution having the corrected concentration and properties is prepared,as determined by the volume measuring system and sensors, the computercan open the valve at the bottom of the chamber to dispense the solutionto the solution manifold, optional sterilization tank, and finalreceptacles. The computer may also activate a vacuum or pressure systemto assist in conveying the final solution to the receptacles. Thecomputer software may then initiate a cleaning cycle to assure that allof the components and compartments are rinsed, clean and dry to preventcontamination of any successive solution to be prepared. Each of theother components of the system may be connected to the computer withsuitable sensors and actuators to permit additional computer control andfeed-back as is known in the art of equipment automation.

In one or more exemplary embodiments, the functions described may beimplemented in hardware, software, firmware, or any combination thereof.If implemented in software, the functions may be stored on ortransmitted over as one or more instructions or code on acomputer-readable medium such as non-transitory computer readablemedium. Computer-readable media includes both computer storage media andcommunication media including any medium that facilitates transfer of acomputer program from one place to another. A storage media may be anyavailable media that can be accessed by a computer. By way of example,and not limitation, such computer-readable media can comprise RAM, ROM,EEPROM, CD-ROM or other optical disk storage, magnetic disk storage orother magnetic storage devices, or any other medium that can be used tocarry or store desired program code in the form of instructions or datastructures and that can be accessed by a computer.

A person of ordinary skill in the art will recognize other modificationsand variations including changes in the arrangement or sequence of theinventive features and operations described above. All suchmodifications and variations are intended to be within the scope andspirit of the present invention, as set forth in the following claims,and not limited by the particular embodiments or specific examplesdetailed above which are only intended to illustrate some of thevariations and preferred embodiments of the present invention.

What is claimed is:
 1. A solution preparation apparatus, the apparatuscomprising: a plurality of containers for holding solid or liquidingredients; a dispensing mechanism in flow communication andoperatively associated with each container that selectively andsequentially dispenses an amount of one or more ingredients; a balancethat sequentially receives the dispensed ingredients and weighs in acumulative way each received ingredient; a supply that provides liquidto the balance for removing the ingredients from the balance and forms aconcentrated solution; and a mixing chamber that receives theconcentrated solution and additional liquid to adjust and prepare aliquid mixture of a predetermined concentration, wherein the mixingchamber has a chamber wall.
 2. The apparatus of claim 1, which furthercomprises: a solution distributor in fluid communication with thechamber that conveys a discharged solution into receptacles.
 3. Theapparatus of claim 2, which further comprises: a processor forcontrolling a dispensing, weighing, mixing, adjusting and dischargingprocess.
 4. The apparatus of claim 1, which further comprises: one ormore liquid ingredient dispensers that can provide one or more liquidingredients to the chamber.
 5. The apparatus of claim 1, which furthercomprises: a volume detector in operative association with the chamberfor determining a volume of the solution within the chamber.
 6. Theapparatus of claim 5, wherein the volume detector comprises: an infraredlight source; a floating disc; and a detector in operative associationwith the light source and the floating disc that measures a liquid levelin the chamber.
 7. The apparatus of claim 1, wherein the chamber wall isinsulated for maintaining the chamber at a consistent temperature. 8.The apparatus of claim 7, which further comprises: heating and coolingjackets within the chamber wall that facilitates adjusting thetemperature of the chamber and the solution.
 9. The apparatus of claim2, wherein the solution distributor further comprises: a sterilizationtank for eliminating biological organisms and contaminants and amanifold, wherein the sterilization tank is located between and is inliquid communication with the chamber and the manifold.
 10. Theapparatus of claim 2, which further comprises: filters for removingparticulates from the solution before dispensing the solution intoreceptacles, wherein the filters are located in and are in fluidcommunication with the solution distributor.
 11. The apparatus of claim1, further comprising probes associated with the mixing chamber formonitoring chemical and physical properties of the solution.
 12. Theapparatus of claim 1, which further comprises: a plurality of separatecompartments, wherein each separate compartment houses a differentsection of the apparatus, and wherein the compartments can be sealedfrom an outside atmosphere by one or more airtight doors.
 13. A solutionpreparation apparatus, the apparatus comprising: a plurality ofcontainers for holding ingredients; a dispensing mechanism in flowcommunication and operatively associated with each container thatselectively and sequentially in a cumulative way dispenses an amount ofone or more ingredients; a balance, wherein the balance has a balanceplate suitably dimensioned for receiving and suitably dimensioned forweighing in a cumulative way a plurality of sequentially dispensedingredients at the same time without loss of any ingredient from thebalance plate; a supply that provides liquid to the balance for removingthe ingredients from the balance and forms a concentrated solution; anda mixing chamber that receives the concentrated solution and additionalliquid to adjust and prepare a liquid mixture of a predeterminedconcentration, wherein the mixing chamber has a chamber wall.
 14. Asolution preparation apparatus, the apparatus comprising: a plurality ofcontainers for holding ready to plug and use canisters; a plurality ofconduits, wherein a single conduit is connected to and in flowcommunication with an egress end of one of the plurality of containers;one or more canisters containing solid ingredients placed within arespective container, and connected to the egress end of the containerso as to form an airtight seal between the canister and the conduit; adispensing mechanism comprising: a plurality of valves connected to andin flow communication with the plurality of conduits; and a dispenserblock supporting the valves and conduits, such that the dispensingmechanism is operatively associated with each container that selectivelyand sequentially dispenses an amount of one or more ingredients; abalance comprising: one or more balance plate(s) that sequentiallyreceives the dispensed ingredient(s) from an egress end of each of theplurality of conduits, and weighs each received ingredient; a supplythat provides liquid to the balance for removing the ingredients fromthe balance and forms a concentrated solution; a chamber that receivesthe solution of ingredients and liquid from the balance; a volumesetting system that determines a volume of the solution within thechamber; a pump that delivers liquid to the chamber until the volumesetting system indicates the solution has reached a predeterminedamount; and a valve that releases the solution from the solution into amanifold that dispenses the released solution into one or morereceptacles.
 15. A method for preparing solutions which comprises:providing a plurality of ingredients; selectively and sequentiallydispensing the ingredients from ingredient containers into a weighingzone, wherein amounts of the one or more ingredients dispensed into theweighing zone are each individually controlled by a computer actuatedvalve; receiving the ingredients selectively and sequentially in theweighing zone, wherein each dispensed ingredient is separately weighed;providing a liquid solvent; spraying the liquid solvent into theweighing zone for rinsing the dispensed ingredients from the weighingzone; rinsing the one or more dispensed ingredients from the weighingzone into a chamber with a spray of the liquid solvent and forming aconcentrated solution; receiving the concentrated solution from theweighing zone in the chamber, providing the liquid solvent to thechamber to dilute the concentrated solution; diluting the concentratedsolution from the weighing zone with additional liquid solvent toprepare a solution of a predetermined concentration; and discharging thesolution of predetermined concentration from the chamber to one or moresolution receptacles.
 16. The method of claim 15, further comprising:providing one or more liquid ingredients; injecting one or more of theliquid ingredients into the concentrated solution received in thechamber, wherein the liquid ingredients adjust one or more properties ofthe concentrated solution; and recording the chemical and physicalproperties of the solution.
 17. The method of claim 16, wherein theproperties adjusted by injection of liquid ingredient includes pH. 18.The method of claim 15, wherein the final solution comprises a food,chemical or pharmaceutical preparation.
 19. The method of claim 15,wherein the ingredients comprise a food, pharmaceutical or a chemicalingredient, acids, bases, buffers, detergents, solutions of acids,bases, buffers, solvents, organic liquids, natural liquids or acombination thereof.
 20. The method of claim 15, wherein the ingredientsare solid ingredients.
 21. The method of claim 15, wherein the finalsolution comprises preparation of buffers, culture media, mobile phases,dyes or electrophoresis gels.
 22. The method of claim 20, wherein thesolid ingredients comprise a powder, crystal, pellet, grain, flake,filing, shaving or dust or a combination thereof.
 23. A non-transitorycomputer-readable medium that stores computer-readable instructions forexecution by a processing system, the computer readable instructions forpreparing a concentrated solution comprising: instructions to activate avalve for selectively and sequentially dispensing ingredient(s) fromingredient containers into a weighing zone; instructions to separatelyweigh each of the selectively and sequentially dispensed ingredient(s);instructions to activate a pump for providing one or more liquidingredients for rinsing the one or more dispensed ingredients from theweighing zone into a chamber; instructions to activate a pump forproviding a liquid solvent to the chamber to dilute the concentratedsolution; and instructions to open a valve for discharging the solutionof predetermined concentration from the chamber to one or more solutionreceptacles.
 24. A solution preparation apparatus, the apparatuscomprising: a plurality of containers for holding ingredients; adispensing mechanism in flow communication and operatively associatedwith each container that selectively and sequentially dispenses anamount of one or more ingredients, wherein the ingredients can be acids,bases, buffers or detergents or solutions of acids, bases, buffers ordetergents or solid ingredients; a balance, wherein the balance has abalance plate suitably dimensioned for receiving and suitablydimensioned for weighing in a cumulative way a plurality of sequentiallydispensed ingredients at the same time without loss of any ingredientfrom the balance plate; a supply that provides liquid to the balance forremoving the ingredients from the balance and forms a concentratedsolution; a mixing chamber that receives the concentrated solution andadditional liquid from the balance to adjust and prepare a liquidmixture of a predetermined concentration, wherein the mixing chamber hasa chamber wall; a probe associated with the mixing chamber formonitoring a chemical and physical property of the solution; a pump thatdelivers liquid to the chamber until a volume setting system indicatesthe solution has reached a predetermined amount; a valve that releasesthe solution into a manifold that dispenses the released solution intoone or more receptacles; and a plurality of filters for removingparticulates from the solution before discharging the solution into oneor more receptacles, wherein the filters are located in and are in fluidcommunication with a solution distributor.
 25. The apparatus of claim24, which further comprises: heating and cooling jackets within thechamber wall that facilitates adjusting the temperature of the chamberand the solution.